Type casting and composing machine.



J. 8. BRAND & F. A. J'OH NSON. TYPE CASTING AND COMPOSING MACHINE. I

APPLICATION FILED MAY 2. I910.

' Patented Mar. 7,1916.

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J. 8. BRAND & F. A. JOHNSON. TYPE CASTING AND COMPOSING MACHINE.

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- iwe tor Emi ,5 Jodnsow J. S. BRAND & F. A. JOHNSON. TYPE CASTING AND COMPOSING MACHINE.

APPLICATION FILED MAY 2, I9l0. 1,174,049. Patented Mar. 7, 1916.

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Patented Mar. 7, 1916.

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J. 8. BRAND & F. A. JOHNSON. TYPE CA STING AND COMPOSING MACHINE.

Patented Mai. 7,1916.

I1 SHEETS APPLICAI'ION FILED MAY 2, 19I0.

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J. S BRAND 8L F. A. JOHNSON. TYPE CASTING AND COMPOSING MACHINE.

APPLICATION FILED MAY 2, 1910.

Patented Mal 7, 1916.

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APPLICATION FILED MAY 2, I910.

Patented Mar. 7, 1916.

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J. S. BRAND & F. A. JOHNSON. TYPE CASTING AND COMPOSING MACHINE.

APPLICATION FILED MAY 2. 19ml 1 1 74,049. Y Patented Mar. 7 1916 I] SHEETS-SHEET 8.

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TYPE CASTING AND COMPOSING MACHINE.

' APPLICATION man MAY 2. 1910.

Patenfed Mar. 7, 1916.

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TYPE CASTING AND COMPOSING MACHlNE.

APPLICATION FILED MAY 2. 1910.

Patented Mar. 7, 1916.

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fiat-messes 1% @2121 finm a3 i I up .I. 8. BRAND & F. A. JOHNSON. TYPE CASTING AND COMPOSING MACHINE.

APPLICATION FILED MAY 2, 19m;

Patented Mar. 7, 1916.

ll SHEETS-SHEET ll- 6 J ifm m UNITED STATES PATENT OFFICE. 4

JOHN S. BRAND, OF FAIRH AVEN, MASSACHUSETTS, AND FRANK AMOS JOHNSON, OF

' JERSEY CITY, NEW JERSEY.

TYPE CASTING AND COMPOSING MACHINE.

To all whom it may'conce'rn:

Be itknown that we, JOHN S. BRAND, a citizen of the United States, and a resident of Fairhaven, Massachusetts, and FRANK AMos JoHNsoN, a citizen of the United States, and a resident of Jersey City, New Jersey, have invented certain new and useful Improvements in Type Casting and Composing Machines, of which the following is a specification.

Our invention relatesto type-casting and composing machines-especially to a machine for casting job and display type in the order of composition and assembling the lines in a galley. The machine may, however, be used as a simple type-casting machine, to cast type for the case.

At the present time most jobs requiring display type are set from the case by handthe type being purchased from type founders, or cast on a machine and distributed into the case by the printer. It has been our aim to produce a cheap and eflicient casting machine, which can be operated by any person 'of ordinary intelligence and *one Which will do in job and display work, what several 'forms of composing machines now do in straight composition.

The particular features of our invention will be pointed out in the following specification and more particularly defined in the claims, reference being made to the accompanying drawings, in which Figure 1 is a plan; Fig. 2 is a front elevation, only a portion of the legs being shown; Fig. 3 is a full left elevation; Fig. 4 is a rear elevation, with the metal pot and galley removed; Fig. 5 is a right sectional elevation, about on line XXX of Fig. 2; Fig. 6 is a right sectional elevation, about on line Y--Y of Fig. 1; Fig. 7 is a partial left sectional elevation about on line ZZ of Fig. 1; Fig. 8 is a partial front sectional elevation about on line WW of Fig. 1; Fig. 9 is a section through the jet chamber, on line V-V of Fig. 4; Fig. 10 is a perspective view of a jet; Fig. 11 is a horizontal section, about on line UU of Fig. 2; Fig. 12

is a left sectional elevation, about'on line TT of Fig. 2; Fig. 13 is a front elevation of the lower half of a type mold; Fig. 14 is a perspective of a space; Fig. 15 is a section of a portion of the mold, on line S S of' Fig. 13; Fig. 16 isa side elevation of a fin- Specification of Letters Patent.

-ished type; Fig. 17 is a right elevation of the matrix carrier or platen, complete with allnlng slide and matrix; Fig. 18 is a right elevation of the matrix alining slide; Fig.

19 is a rear elevation of the matrix platen complete with alining slide and matrix; Fig. 20 1s a top view or plan of a matrix; Figs.

21 and 22 are side and rear elevations respectively of a space matrix; Fig. 23 is a front elevation of a space, as cast from one of the Patented Mar. '7, 1916.

Application filed May 2, 1910. Serial No. 558,799.

the cap plate 24 and mold, as shown in Fig. 8.

General description...

The mold is quite similar in shape to those of the old-style type casters, which were in almost universal use before the advent of the perfecting machine and consist of two similar, obverse portions or halves. That is, there are top and bottom cheek pieces, between which are two pieces which determine the body of the type and form the side walls of the moldone being fastened to the upper cheek piece and one to the lower. Instead of swinging apart, as in the old-style machine referred to, the two portions of the mold are adjusted longitudinally, one part on the other, tovary the mold opening, and the mold reciprocates in a mold runway, which allows it just a running clearance. There are no nick-forming ribs in the mold and the two parts are held in register by tongue-and-groove plates on the face of the mold. This construction permits the type which'are cast being pushed out of the mold by an ejecting plunger. The'mold has a reciprocating movement from left to right a type being cast when the mold is at the left and ejected when it is at the right. The lower cheek piece, which carries the left hand portion of the body piece, comes back to a fixed position every time a type is cast a suitable stop being provided for it to come up to. The upper cheek piece or portion of the mold carries a bumper plate, which is adapted to strike against a matrix block and limit it in its movement. After the lower portion of the mold is brought to casting position amatrix is brought up against it, but with no perceptible pressure on it; the upper portion is then moved, yieldingly, until the bumper plate strikes the matrix to limit the mold opening to the proper size for that particular character.the matrix blocks was a jet chamber, formed by parts which were attached to the upper and lower portions of the mold. We provide a separate integral slide, which has a jet-forming chamber. This slide moves at right angles to the mold movementi. 6., it has a vertically reciprocating movement, while the mold moves horizontally. The downward movement of the jetslide precedes the movement of the mold to the right, thereby cutting oif the jet; and as the type is ejected from the mold a second finger, which is operated by the same cam, ejects the jet from the jet chamber. This construction is very advantageous, as one jet slide serves for all body sizes which can be cast on the machine. In changing from one body size to another all that has to be changed is the two portions of the mold proper, which are exact duplicates of each other, except the front plates and, being of very simple construction, can be cheaply made. The molds are the most expensive part of a type-casting machine and this construction enables us to furnish a machine with a wide range of body sizes, at comparatively small cost.

In all type casting and composing ma chines with which weare familiar, there is a matrixor d1e-case and a key-board mechanism; or a complete set of matrices attached to or controlled by a bank of keys and connections therefrom. We greatly simplify the construction by dispensing with the die-case as ordinarily understood and all key-board mechanism. We use a set of separate, disconnected matrices, which are arranged in separate compartments of a trayone six or seven inches square being large enough to contain all'the characters of a font of type. These matrices are sufficiently large to be easily picked up and handled, and they have the characters plainly marked on their upper ends.

In front of the mold there is a reciproeating matrix carrier, which is quite similar to the platen of an ordinary job printing press. This platen is adapted to receive a matrix, carry it up to the mold, hold it there long enough to cast a type, and return with it to the starting point. The matrix is not gripped in any way and can be picked up from the platen without having to release it in any way. The tray of matrices is mounted on a-suitable bracket which extends forward from the machine and is in close proximity to the matrix platen. The operator picks up the matrix he wants, places it on the matrix platen and touches a starting key,"which is arranged in a convenient position. This calls into action a cam shaft and causes it to make one revolution and stopthe one revolution of the shaft controlling the complete cycle of op-.

erations which are necessary to cast and eject .a type. The stopping point of the shaft is, however, in the middle of the cycle of operations: 2'. e., as the first matrix is placed on the platen and the starting key is struck, the machine goes through the motions of ejecting a previously cast type before the mold is brought into position to cast a type from the matrix which has just been inserted. The matrix platen holds the matrix .against the mold long enough for the face of the type to solidify and then it is withdrawn, so that another matrix can be substituted; but the mold remains locked until the machine is again started. This gives the type time to cool, while the matrices are being changed, which is necessary, in casting large sizes of type, in order to prevent swelled bodies. A waterjacketed mold is used, but as there is nothing novel in such a device, it is not shown in the drawings.

The whole operation is very similar to feeding cards to a job press.the matrix just used being removed by the left hand and returned to its compartment, just as a card would be removed and the next succeeding matrix is inserted with the right hand, just as a card would be placed on the gage pins. The stops on the platen, which correspond to the gage pins of a job press, are tongued and the matrices are grooved on the bottom and left hand sides to match these tongues. This arrangement strips the matrix from the cast type just as the gripperfingers of a job press withdraw the printed card from the form. Both the bottom and side gages are mounted on an independent slide which is carried in the face of the platen. This slide moves up and down. The side gage is, therefore, constant for all matrices. The slide is shifted to change the register of the matrix on the molda stepped piece being interposed between the platen and the slide and a suitable pointer and scale is provided which indicates the exact position of the slide. This arrangement permits the. alinement of the type to be changed at will. A 6-point letter can be placed in any position on a 36-point body, for instance.

The advantage of having different size faces cast on one body is so great that the type foundries now furnish, in faces frequently used, three and sometimes four dif ferent sizes on one body. To make such a system universal would require so many different cases and so much type that it would be prohibitive for the ordinary printer. Our machine enables the printer to have all these advantages without any additional cost. Not a single type need be cast that is not to be used on a given job.

Instead of having to put leads at the top and bottom of a small body size of type in order to make it line with a larger size,

the operator simply shifts the register slide on the matrix platen and the small size face is cast on the large size body in any desired position, giving the possibility of an almost infinite number of combinations.

In the die-case and key-board type of machine the number of characters is limited, unless the die-case is made unwieldlyexcept by a change of the die-casean operation which takes time. In our machine, one tray may be substituted almost instantly and, the matrices being independent and disconnected, they may be selected from other trays, within the convenient reach of the operator. This increases the capacity of our machine from two or three hundred sizesthose which will cool during onecycle of the cam shaft without-stopping nothing is necessary except to place the matrix of the character desired on the platen and hang a weight on the starting key, or lock'it down in any other manner. In casting larger sizes, weprovide an automatic starting device. The cam shaft stops each time a type is cast and, as soon as sufficient time has elapsed for the large type to cool, the starting device trips the clutch and starts the shaft off again. This device consists of a weighted lever, whichis raised by the cam shaft and released just as the shaft reaches its stopped position. As the weight ed lever falls it is adapted to operate the clutch the same as the starting key. The

clamped and carried to the right. If the type which has been cast is not wider than the ejecting finger, or if no type has been cast, the upper portion of the mold is moved a greater distance than the lower portion, in

order to insure an opening for the ejecting finger which comes forward at this time to eject the type forward onto the type way and in front of a type hook-a light friction blade being provided for them to come under. The type hook carries the type to the right over a nick cutter and past a foot planer. This gives the type its two feet to stand on and makes a small nick, which is desirable in correcting proof. For ordinary purposes no other nlcks are necessary and the molds are reduced in cost by dispensing with the nick-forming rib. Where the type are to be put into a case to be used over and over again, identifying nicks may be milled in them, on a separate machine and all the different faces which are cast on one body may be plainly distinguishedthus avoiding the annoyance which is now experienced in type obtained from the foundries, where they often cast several similar faces on one body with identical nick markings.

Shoulder-high spaces are produced by putting in a blank matrix block. Low spaces and quadsare produced in a manner quite similar to that described in U. S. Patent 862,800, to W. E. Brand-i. e., by cut ting off the end of a shoulder-high space, on its passage from the mold to the point of assembly. Instead of using a saw, as in the Brand patent referred to, we use a chisel. This chisel is arranged along the typeway, between the point where the type come out of the mold and the line of assembly and its movement is controlled by a trigger device. When a type is ejected from the mold it strikes against a light trigger arm. Connections are made which ren- 1 der the chisel inoperative for that revolution of the shaft. The type stops under the chisel, on its way to the line, but the chisel does not move and it is not touched. When a shoulder-high space comes out of the mold it is too short to operate the trigger and as the type hook carries it to the right it stops under the chisel and the chisel,

not having been thrown off, is drawn down I and cuts off, say, one-eighth of an inch from the end of the space and makes it about the same height as a foundry low space. It is then carried on to the right into the line, the same as a type. Shoulder-high spaces are reduced, in this manner, without difiiculty, in the smaller sizes of type and the chisel has an advantage over a saw, in that it is cheaper to make; easier to operate; and does not produce any fine dust. In the larger sizes of type we use a special matrix for casting the spaces, which make it easier for the chisel to cut off the, end. These space matrices have lugs which are adapted to enter the mold chamber the distance which it is desired to shorten the space say one-eighth of an inch. These lugs are,

in cross section a little less than the cross I section of the mold .chamber. A space cast from such a matrix has a box-like end, with very thin walls, which is easily cut oil by the chisel and there is no limit to the size body or width of space which may be made, so far as the cutting off the ends is concerned.

We are aware that low spaces have been cast by inserting a block which entirely fills the mold chamber to the depth to which it is desired to reduce the space. This method is objectionable in that, in moving in and out of the mold. it is bound to wear the walls of the mold chamber and hence, in time, impair the accuracy of the type cast in the mold. In our device, the matrix lug which is inserted, does not touch the walls of the mold chamber at any point. We depend on the chisel or other cutter to shorten the spacethe block on the space matrix simplv reduces the amount of material that has to be removed so that it comes easily witliiin the capacity of the cutter which is use As the type are carried to the right they are assembled on a swinging line blade, against a receding friction slide which is carried by the blade. On the completion of a line it is pushed to the extreme right, by hand, and swung upward and backward and deposited in a galley. The blade will fall by gravity and the slide is moved to the left to receive the first type of the next succeeding line.

The metal pot, which contains the molten metal, has a piston, which is locked up under spring tension and released at the proper time in the sequence of operations, to inject metal to form a typeprovided there is a matrix in place and provided it is properly seated on the mold. Otherwise, a safety device will prevent the pump from being released. 1

The nipple or snout is long and tubular in shape and the front end, or nipple proper, is of an improved construction, which gives a short abrupt turn to the passage of metal and permits the metal being kept right up to the outleta sliding valve acting, in one position, to allow the pump well to fill and the surplus metal to run back into the pot and,'in another position, the overflow port and intake ports are closed and a port leading directly from the well to the mold chamber'is opened. This enables us to eject the metal horizontally, without the use of a choker valve and with practically no air to expel from the metal passageway and permits of a proper actionof the pump as long as there is any metal left in the pot.

The pump piston, in its downward stroke, cushions on the metal and it is locked against further downward movement before the valve is shifted. The pump, therefore, makes only so much of a stroke as is necessary in order to produce the type which is being cast.

as it is injected into the mold chamber.

Description in detail.

General frame-work, cam-shaft, driveskaft, drc.The mold, assembling mechanism, cam-shaft and most of the moving parts of the machine are mounted on, attached to, or secured in an upright 1. This upright is bolted to the top of a bed-plate 2, which is supported by a pair of legs 3. At the back of the upright, held in boxes 4, is the camshaft 5, which carries all the cams which are necessary to produce the automatic movements which are necessary to operate the various parts of the machine. This shaft carries, in its right hand end, a pivoted clutch pawl 6, one end of which seeks engagement with a drive clutch 7, by reason of a spring 8, but which is normally held out of engagement by its other end resting on a stop-wedge 9, which is held by a swinging arm 10. The clutch 7 is carried by a shaft 11, which turns in a bracket 12 and which is kept constantly running by power applied to a pulley 13, on its outer or right hand end. On touching a starting key, the arm 10 is raised as will be pointed out-allowing the clutch pawl to engage the clutch and to carry the shaft '5 once around, when it will be stopped by the wedge 9 disengaging the pawl.

Type-mold, mold-moving levers, etc.

The type mold is composed of upper cheek piece 14, to which is fastened its portion 15, of the body piece, and the lower cheek piece 16, with its portion '17, of the body pier" (See especially Figs. 8, 11 and 13.) i

lower cheek 16 has two guide plates 18,

which are cut out so as to form grooves 19. The upper cheek has, on its left end, a plate 20 with a tongue 21, which enters the groove 19 of the left hand plate 18. On the right hand end of the upper portion of the mold is a bumper plate 22, tongued on its lower edge, to enter slot 19 of the right hand plate 18, This construction holds the front and rear faces of the mold in accurate register, while permitting a longitudinal movement of the parts on each other, to vary the width of the mold chamber 23.

At the top of the upright 1, there is a cap upright and a latch pin 29 holds the cap plate in a horizontal position so that its lower edge is parallel with theupper edge of the, uprightit being placed just far enough away to allow a running fit for the mold.

The lower portion of the mold is carried by a yoke 30, which slides in a groove 31, which is cut in the upper edge of the upright. The upper portion of the mold is carried by a similar yoke 32 which slides in a groove 33 which is cut in the lower edge of the cap plate. Fins 34, in the upper and lower cheek pieces, acting against the upper and lower mold yokes, while permitting of a slight lateral movement, which is necessary for clamping themold, prevent it from being pushed forward as the type are ejected.

The lower portion of the mold is moved by a lever 35, which is pivoted to a fulcrum block 36, which block is secured to the front face of the uprightthe lower end of the lever carrying a roll 37, which enters a cam slot 38 of a cam 39, near the left end of the cam shaft. Connection is made from the upper end of the lever to the mold yoke 30,

by means of an adjustable link 40. This portion of the mold 1s accurately located by being drawn against a stop 16, which is secured to the upright near the left end of the mold run-way and which is shown only in Fig. 8. The upper mold yoke 32, is connected by a link 41, to the upper end of a lever 42connection being made by a screw 43, of the lever, through a slot 44, of the link. A spring 45, tends to draw the upper half of the mold to the left and to keep the right hand end of slot 44 up against the screw 43. The lever 42, has the same pmnected by a link 46 to the upper end of cam lever 47, which lever is pivoted to the bed plate 2, and which has a roll '48, restin against a side cam 49, on the extreme left end of the cam shaft. The lever 42 is longer than the lever 35 and when the two levers are in their left hand position, it rests against a pin 50 in the lever 35. .When the link 41 is at the left, up against its pin, the mold chamber is closed. It is evident that, as the lever 35, which controls the movement of the lower portion of the mold is carried to the right, that the upper portion will be moved a greater distance, by reason of its increased length of lever. The mold will, therefore, always be open far enough to allow the ejecting finger to enter, as will be pointed out. The lever 35 has an adjusting screw 51, which acts against the lever 47, to limit the maximum distance the mold may be opened. Y

Matrix pZaten.The matrix platen 52 is pivoted or hinged on the front side of the upright, between the latch-block 27 and a box or keeper 53 (see Figs. 2, 6, 17, 18 and 19) by a pin 54 and has a register slide 55, which carries a lower gage piece 56, and a side flange or gage 57. The register slide has a pin 58, which rests on a stepped disk 59, in the matrix platen. This disk may be turned by a small shaft 60, which has a pointer 61, which moves over a scale 62, on the front face of the platen. By turning the pointer, the register or alining slide may be set to any desired height, as stated in the general description. 1

The matrix, m, is shown clearly in Figs. 17, 19 and 20, and consists of a block 64, which incloses or carries a portion 65, with the actual matrix character 63. The matrix block has, on its under side, a groove 66, which is adapted to be entered by a tongue 67, of the lower gage 56, when the matrlx is placed in position on the platen. The side flange, 57, has a tongue 68, whlch 1s adapted to enter a groove, 69, in the left side of the matrixlblock. The back of the matrix blockthe side toward the front of the machinehas a raised portion, 70. This is exaggerated in the drawings, as the hump is barely perceptible-just enough to permlt the matrix to accurately seat itself on the face of the mold, when pressed agamst it by the matrix platenthe bottom and side grooves in the matrix block fittingthelr respective tongues loosely to permit of the matrix block turning slightly.

The ordinary way of seating a matrix is by a pointed plunger, which is adapted to enter a hole or dent in the back of the matrix. Such an arrangement, while effective, would require the shifting of thepoint for every different width of matrix block. Our device is adapted to receive matrices of all i l p i t a the l r 35 and it i n, fwidths, within the capacity of the machine, 9

and to accurately seat them on the mold, without any adjustment whatever, from one size to another.

The movement of the matrix carrier or platen is effected by means of an impression lever 71, which is pivoted to the fulcrum block 36. The lower portion of this lever is forked: one portion, 72, has a roll, 73, which bears against a cam, 74; the other portion, 75, has a roll, 76, which, bears against a cam, 77. These two cams control the movement of the lever 71, which is connected to the matrix platen, yieldinglyits upper end, 78, being joined to the lever proper by means of two 'stifi' springs, 79. The end 7 8, carries a roll, 80, which bears against the platen and which has a pin, 81, which is engaged by a flanged plate, 82. As the lever 71 is drawn forward the platen is pulled positively away from the mold.

From the foregoing construction it will be seen that the matrices are placed on the matrix platen very much in the same manner that cards are placed against the gage pins of an ordinary job printingpress, that they are held to Positive movement to and from the mold and that they are as freely removable from-the platen as cards are from a job press.

It will be noticed, by reference to Fig. 19, that the register or alining slide, 55, fits loosely in the platen at its upper end; that it could be moved sidewisel were it not for a block, 83, which is interposed between said slide and the latch block 27. v This block is I very slightly tapering and the parts are so made that, when in its rearmost position against the mold, the register slide is exactly vertical. As the mold is moved to the left the matrix platen with the matrix is advanced toward the mold. Immediately the lower portion of the mold reaches its extreme left position, against the stop 16 the matrix is advanced up to the mold, but with no perceptible pressure, as already stated. The upper portion'of the mold is then drawn over by the lever 42 and connections, until the bumper plate, 22, strikes against the matrix block which is on the platen; after which, the spring 45 yields. As the matrix has to be withdrawn before the mold is again moved to the right, it is. necessary to remove the pressure which has been put against the side of the matrix, in order to get it away easily. While ,this might be done in various way, the wedge 83, is a simple and efiective means of doing it. With the slightest movement forward of the matrix platen the matrix is free.

The upper portion of the mold being drawn to the left yieldingly, as already explained, and being limited in its movement by the matrix which is interposed in the path of the bunter plate 22, it is evident that the width of the mold chamber 23 will vary according to the width of the matrix m which is placed on the matrix platen and seated on the mold. The matrix, therefore, becomes its own gage for regulating the running width or set-way size of the type which is cast. In Fig. 8, the position of a matrix on the mold is indicated by a dotted rectangle 712/. In this view the mold chamber 23 is set to cast about a 2-em character or space. A thin character would have a narrower matrix and the bunter plate 22 would move on farther tothe left before being stopped by the matrix and the mold chamber would be closed up to correspond with the character or type that was being cast.

Mold-locking dem'ces.During the timebears against the upper mold yoke 32. This bolt is driven downward by a rock-shaft, 85, which is flattened off so as to act as a lever, as shown in Fig. 8said shaft having, on its rear end, an arm, 86, which is actuated by a spring, 87. This arm is raised by the upper end of a long rod which, for convenience, is made in two pieces, 88 and 89the upper portion, 88, being curved. The lower portion, 89, carries a cam roll, 90, and is moved by a cani, 91, on which it rests (see Fig. 4).

In order to prevent the mold being forced open by the pressure of the metal overcoming the pressure of the spring 45 and friction caused by thelocking bolt 84, we provide an auxiliary end look. In the upper edge of the connecting link 41 there are notches, 92, which are adapted to be engaged by a pawl, 93, which hangs from the lower end of a slide, 94, which is held in a keeper, 95-the keeper being attached to the left end of the cap plate, 24. A spring-seated bolt 96 having a spring 96*, tends to carry the slide and pawl downward. Normally it is held upward, out of engagement with the ratchet teeth, by the locker rod, 88, which acts on a pin, 97 which is in the upper end of the slide. With the first downward movement of the locker rod the pawl, 93,

enters one of the notches, 92, of the connecting rod-thereby preventing the upper half of the mold moving to the right until the pawl is released. The left end of the pawl hangs lower than its pivotal point to the slide 94the action is, therefore, like that of a toggle andthe pawl tends to aid the spring 45, in closing the bumper plate tightly against a matrix block.

J et sZz'de.Just back of the mold, on the back of the upright, there is a jet-slide, 98, which is vertically movable between the upright and a side gib, 99, and which is held in by keepers, 100. This slide has a jet chamber, 101, through which the metal flows into the mold chamber.

103, and to which the slide is connected by alink, 104the shaft being rocked. so as to throw the arm onto dead centers in upper and lower positions, by means of a pinion, 105, on the left end of said shaft, just outside the upright. This pinion is in mesh with a sector gear, 106, which has front and rear arms 107 and 108, with rolls 109 and 110, respectively-the forward roll being acted on by a'cam 111, and the rear one by a cam, 112. These two cams control the movements of the jet-slide, through the parts just pointed out. The jet chamber is provided with side grooves, 113, as shown in Fig. 9, so that the jets, 114, are formed with ribs, 115, which insures the jets being ejected straight backward and fully out of the jet chamber.

Melting pot and metal-injecting mechanism.The melting pot, 116, is carried by a casing, 117', which is held by side legs, 118, which are pivoted at the front to left and right arms, 119 and 120, which arms are secured to a rock-shaft, 121-said shaft rocking in a pair of brackets, 122, which are fastcned to the upper surface of the bed plate. A pair of idle links, 123, at the rear, connect the legs of the casing to the rear ends of the supporting brackets, 122. The left arm,

119, has a handle, 124, by means of which the shaft, 121, may be rocked to put the pot in its casting position, as shown in Figs. 2 and 6, or to let it back out of the way, as shown in Fig. 7

The snout 125 of the pot is tubular in form and has a nipple, 126, which is formed with a core, 127. There is an opening, 128, through an apron, 129, into the mold. By this construction of the nipple, it is possible to get an abrupt short turn in the metal passageway, 130, as already stated. A pump piston, 131, is attached to and operated by a pump lever, 132, which is pivoted by links, 133, to the pot. To the back of the casing is attached an L-shaped bracket, 134, which guides and supports the lower end of a pump rod, 135. A spring, 136, connects the pump lever to the L-bracket. When the pump rod is kicked off its ledge plate, 137, of the L-bracket, the spring acts to draw down the piston and force the metal through a port, 138, in a valve slide, 139; thence through passage ways 140 and 130, into the mold.

' The pump rod is kicked ofl by a horizontally sliding rod or bar, 141, the forward end of which is held in and guided by a bracket, 142, which is attached to the front side of the pot casing. This rod is moved by one arm of a three-armed lever, 143. This lever is pivoted to a lug 144, of the upright and it is actuated by a spring, 145, when the middle arm, 146, which has a roll, 147, bearing against a cam, 148, permits it to act provided also, that the horizontal arm, 149, which is pivoted at its front end to a vertically sliding bar, 150, and to which the safety device already referred to is attached,- is free at the same time, as will be pointed out later.

Attached to the L-bracket is a pawl, 151, which is caused by a spring, 152, to seek engagement with teeth, 153, of the pump rod, 135. The pawl is held out of engagement with said teeth by a rod, 154, during the time the pump piston is acting to inject the metal.

This rod is mounted in a similar manner to that of rod 141 and it is forced to the rearto free the pawl by a lever, 155, which has its fulcrum in the base flange, 156, of the upright, 2, and which has a roll, 157, bearing against a cam, 158the upper end of the lever being in contact with the rod, 154. As

soon as the pump has acted, this cam permits the spring, 152, to force the pawl, 151, into the teeth, 153, of the pump rod and thereby stop further downward movement of the pump piston, which would otherwise take place, when the pressure was removed by the shifting of the valve slide, 139.

. The valve slide, 139, is operated by a cam, 159, through the following connections: cam rolls 160, 161, which are carried bya cam lever, 162, which is pivoted to a bracket, 163, which bracket is secured to the rear side of the upright; connecting rod, 164, which for convenience is made adjustable; horizontal lever, 165, which is pivoted to the top of the pot and one end of which enters the upper end of the valve slide, 139. lower end of the-connecting rod, 164, is attached or pivoted to the right pot casing leg by an idle link, 166. The rear end of the cam lever 162 is slotted and bell-mouthed and is adapted to receive a pin, 167, which is in the lower end of the connecting rod. This construction permits the pot and casing being thrown back as shown in Fig. 7 and again brought up to casting position, without having to disconnect the parts-the bellmouthed lever picking up the pin of the connectingrod, in whatever positionit may be.

In the position shown in Fig. 6, the valve 139 is open and in position for the piston to force the metal out of the pump well, 170, into the mold, as already pointed out. The valve is raised to close and in so doing the intake well port, 171, is uncovered, permitting the piston as it is raised, to draw in metal through the side openings, 172, to fill the wellthe port 138 being closed at that time. When the valve is in its, pward position, aseeond port, 173, near thetop, registers with an overflow passageway 174, thereby permitting the metal which is in the nipple to recede slightly and prevents it running out into the jet chamber. It will be observed from this construction that, when the passages to the nipple are once full, that the height of metal will be maintained right up to the yery outlet of the nipple, as long as there is any metal in the pot.

The pot is clamped against the mold by two side links, 175, which are pivoted to the upright and which have at their rear ends, a cross-bar 17 6. This cross-oar is held in place by pins, 177. which extend rearward from the casing and on which the bar is free to slide. A clamp screw, 178, which is carried by the cross-bar, acts against the cas ng of the pot to clamp the pot up against the machinethe apron, 129, which rests against the upright and the side gib, 99, taking the strain, giving the jet-slide just a running clearance between the apron on the back side and the upright a 1d cap plate on the front. \Vhen the impression lever acts on the front of the matrix platen to force the mold and jet-slide backward against the apron, the mold having a very slight movement in the carrying yokes, a tight joint is made between the jet-slide and mold and between the apron and jet-slide, so that no metal can escape. I

The pump rod is raised and latched up and the spring, 136 is put under tension by a pawl, 179, which is pivoted to the rear end of an arm 180. This arm is on the right hand end of a short shaft, 181, which rocks in bearings in a hanger, 182, which hanger is secured to the under side of the base plate. The shaft has on its left hand end, an arm, 183, which is connected. by a link or pitman 184 to a crank pin, 185, which is in a crank disk, 186, on the left end of the cam shaft. The crank pin is positioned so that the pawl 179 is low at the time the pump rod is kicked off.

Any approved form ofburner may be usedthe one shown in the drawings needs no explanation. A snout-shield, 187, confines the heat to make it effective where it is most needed and protects the adjacent parts of the machine. A shield, 188, protects the cams, levers, etc., from dirt and metal dropping on them.

Safety devices,- automa-tic throw 0#. If the starting-key should be touched without a matrix in place; or if the matrix should be improperly seated, the pump is rendered inoperative. This is done by locking the kick-off lever 143, which carries the vertical slide, 150, already pointed out. The upper end of this slide has a toe, 189, which is adapted to enter a slot, 190, of a stop-arm, 191 which is piyoted to the fulcrum block,

36', when said slot is inproper register with the toe. A spring, 192, normally holds the arm, 191, rearward. Extending downward from the matrix platen is an arm, 193, which is adapted to strike against a lug, 194, of the arm 191. WVhen the matrix platen is pushed rearward with a matrix, the arm 191 swings forward so that its slot, 190, registers with the toe of the slide 150. If there were no matrix in place the platen would go in farther and an imperfect registering of the toe and slot would result and when the cam, 148, was in position to permit the spring 145 to kick off the pump red, the slide 150 would be locked and it would be unable to trip the ump. In case of dirt between the matrix and mold the platen would be held out and an imperfect registering would result, which would, likewise, render the pump inoperative.

The upper half of the mold, being set for various sizes, has to be carried yieldingly and unless the bumper plate is snug up against the matrix block every time there will be an error in the running widths of the type cast. To prevent this we mount a small bell-crank lever, 195, in the bumper plate (see Figs. 2 and 8). WVhenthe mold is in its casting position at the left, the horizontal arm of lever 195 is in contact with a horizontal lever,.196, which is pivoted to the cap plate 24. 1f the bumper plate comes up against a matrix block the bell-crank lever will raise the end of lever 196. This lever has a pin, 197, which comes in contact with a pawl, 198, which is attached to the upper end of a rod, 199, which slides vertically in the latch block 27. This rod is pivoted at its lower end to the horizontal arm 200 of a three-armed lever, 200, which lever is pivoted to the upright just above the fulcrum block 36. The middle arm 200" of the lever 200 stands normally under the toe 189 which is on the top of the safety slide 150, as indicated by dotted line position in Fig. 2. When a matrix is in position and properly clamped by the bumper block, it is evident that the parts will be in the position shown in Fig. 2 and the pump will be free to act. If the bumper plate should be held back, the lever 196 would not be raised and the safety slide would remain latched up, although the toe 189 might be. in proper register with its slot 190, the pump would be rendered inoperative. An arm, 201, on the shaft 103 at the left of the upright, is adapted to swing round to dotted line position 201 and will strike against the left hand arm .200 of the lever 200, and will insure its positive return to normal latched position, as indicated by dotted lines in Fig. 2.

. Type and jet-ejectors.-An ejecting lever, 202, (see Fig. 7) is pivoted to the hanger 163. It is given a reciprocating movement by two cams, 203, 204, which act on two rolls, 205, which are carried on the lower forked end of said lever. An ejecting finger, 206, slides horizontally in a bracket,

207, which is secured on the rear side of the upright and which is adapted to enter the mold chamber, when the mold is in its right hand position, to eject the type-connection being made to the ejecting lever 202 by an arm, 208. The cams are so timed that the type is ejected-andthe ejecting finger positively drawn back from the mold while the mold is in the right hand position. Simultaneously with the ejecting ofthe type the jets are discharged from the jet chamberthe jet slide being in its lowest position at that time. This is done by a blade, 209, which slides in guides, 210; it being carried by an arm, 211,which is secured to a rock-shaft, 212, which shaft has on its right hand end, an arm, 213said arm being connected by a link, 214, to the ejecting lever 202. The side ribs on the jet, which have been already pointed out, insures the ejecting blade 209 remaining against the narrow end of the jet, while it is being pushed out. The jets being wedge-shaped, it would be, otherwise, a diflicult matter to be sure of always getting them out, of the slide.

Type-assembly meaham'sm.At the right of the matrix platen, secured to a slide, 215, which has a vertical adjustment in the front of the upright is a channeled typeway, 216. A front, inclosing bracket, 217, which also carries the space cuttin chisel, secured to the upright below the slide 215, has a clamp screw, 218, by means of which the way is firmly held in any desired positionit being set so that its upper edge alines with the lower wall of the mold chamber by means of a stepped gage-block, 219, which is interposed between the slide 215 and the bracket 217. Attached to the cap plate 24, is

a vertically adjustable top block, 220, which has a stepped gage, 221, by means of which it can be set sothat the type have just a running clearance between the top block and the type-way. Extending to the left from the top block, is a horizontal stud or post, 222, which carries a rocking blade, 223. This blade isset so that it puts a slight friction on the type as they are ejected from the mold. Sliding in the channeled type-way and guided in a groove, 224, is a .packer slide, 225, having a head, 226, which, in its left hand position, is drawn far enough to clear the type as they are ejected from the mold. The ofiice of the packer is to carry the type to the right and to deposit them on a line blade, 227. This movement is effected by a cam, 228, through the following identified parts: roll 229; lever 230; connecting link 231; lever 232, which is pivoted toits fulcrum bracket 233; and connecting link 234, which connects the top of the lever 232 to the packer slide.

Type-maker and f00t-plane1'.As the type are carried to the right they are driven forward slightly by a foot cam-plate, 235, which insures all the type being out the same distance from the upright. In under the top block and secured to the type-way is a nick cutter, 236, which planes a nick in the type overcome this, we cast the type with a slight recess, 239. This is formed by a pin, 240, in the mold (see Figs. 13-15). It projects into the mold so slight a distance that it does not interfere with the ejecting of the type. This recess is formed in line with the nick cutter and any possible bur that may be left by the cutter will come in the recess and would interfere in no way with the type when they are packed together in a line.

Space-shortening dem'ce.As already stated in the general description, spaces are, or may be shortened, on their way from the mold to the galley, by cutting off their forward ends with a chisel. This chisel, 241, is attached to a vertically sliding bar, 242, which is held by a keeper plate, 243, in the bracket 217. A spring, 244, coiled round a pin, 245, in the upper end of the keeper 243, acts against a cap plate, 246, and tends normally to hold the chisel in an upward position. The lower end of the chisel post 242 is forked and carries a horizontal rockshaft, 247-a latch or pawl, 248, being secured to said shaft and inclosed between the forks of the chisel post. A chisel driver, 249. is attached to the upper end of a rod, 250, which rod is pivoted to the front end of a cam lever, 251. The chisel lever has its fulcrum in a lug, 252, which extends rearward from the upright and it is operated .by a cam, 253, which acts against a roll, 254, on the rear end of the lever. The forward end of the lever and the roll is held' against the cam by a spring 255.

When the trigger latch 248 is swung forward the chisel driver will strike against it and the chisel post will be drawn down, carrying the chisel with it. The shaft 247 extends a little way to the left and has an arm, 256, two pins, 257, in which, inclose the lowerend of a trigger lever, 258.- This lever is pivoted to the bracket 217 and its 

